Business machine

ABSTRACT

A cash register is provided with an accumulator and a display. On ADD cycles of the cash register, the accumulator is moved in one direction to engage the digit tape by a pair of eccentrics, and on TOTAL cycles, it is moved in another direction by another eccentric to transfer digital information to the display. Control of the eccentrics is provided by an axially movable timing gear which provides a modified genevatype mechanical movement.

United States Patent Greskovics [451 Oct. 17, 1972 [54] BUSINESS MACHINE 2,066,669 1/1937 Bilde et a1 ..235/9 2 355,637 8/1944 Faigle ..235/60 R 72 l P l 1 menu" l Greskmcs Manham Beach 2,048,453 7/1936 Kall ..235/60 R 3,331,553 7/1967 Styner ..235/23 RC [73] Assignee: Litton Business Systems, Inc., New

York, NY. Primary Examiner-Stephen J. Tomsky [22] Filed: June 26 1970 Assistant Examiner-Stanley A. Wal

Appl. No.: 50,063

Attorney-Alan C. Rose and Alfred B. Levine [57] ABSTRACT A cash register is provided with an accumulator and a display. On ADD cycles of the cash register, the accumulator is moved in one direction to engage the digit tape by a pair of eccentrics, and on TOTAL cycles, it is moved in another direction by another eccentric to transfer digital information to the display. Control of the eccentrics is provided by an axially movable timing gear which provides a modified genevatype mechanical movement.

8 Claims, 29 Drawing Figures 45! Ava Fart 510110 a; Ala/Mm. 4mg

77MEZ 65,42

PAIENTED OCT l 7 I872 SHEET 1 OF T INVENTOR. PAUL GRESKOVI CS PAIENIEU um 11 m2 SHEET 2 BF 7 INVENTOR. PAUL GRESKOVI CS PATENTED OCT 1 7 I972 SHEET 3 0F 7 Jazz I; wanna an un- RS m V o K WS 6 L U A P PATENTED our 1 1 1912 SHEET 5 OF 7 WZZ/Af 6455.506

INVENTOR. PAUL GRESKOVI CS BUSINESS MACHINE CROSS REFERENCE TO RELATED APPLICATIONS This case is closely related to the commonly assigned application of Kenneth F. Oldenburg US. patent application Ser. No. 50,064 titled BUSINESS MACHINE, filed on June 26, 1970, concurrently with this patent application.

FIELD OF THE INVENTION This invention relates to mechanical mechanisms for business machines.

BACKGROUND AND SUMMARY OF THE INVENTION In the above-identified patent application and in the detailed description which follows, a cash register is described in which the accumulator is moved down into engagement with digit tapes to receive digital input information on ADD cycles, and is moved to the rear to transfer the contents of the accumulator to the display on TOTAL cycles. In the usual supermarket transac tion, a number of ADD cycles occur as the clerk enters the value of specific purchases, and the TOTAL cycle occurs after all of the individual purchases have been entered. The present invention involves the mechanism by which the accumulator register is selectively moved either downward and upward, or to the rear and forward, in accordance with the selected ADD or TOTAL cycle of operation of the cash register.

In accordance with one aspect of the invention, this movement is accomplished by two eccentric assemblies. One of the eccentric assemblies includes a pair of eccentrics at each end of the accumulator carriage which are operated in synchronism. The eccentrics are journaled in the main frame of the cash register and their eccentric surfaces engage the carriage of the accumulator. For movement in one direction, one of the eccentric assemblies is held fixed to serve as a guide, while the paired eccentrics are rotated together to move the entire accumulator carriage. For movement in the other direction, the two paired eccentrics are held fixed to guide the motion, while the third eccentric is rotated to provide a positively controlled movement in the other direction for the accumulator carriage.

A modified geneva mechanism is provided to control the movement of the eccentrics. The paired eccentrics are interconnected by gears so that they rotate together. One of the paired eccentrics is mounted on a shaft which is also provided with a gear forming part of the geneva mechanism. The third eccentric, which provides motion in the other direction, is also provided with a gear forming part of the geneva mechanism.

These two gears coact with a timer gear having a central ridge which extends over its entire periphery. This timer gear is axially shifted to permit selective rotation of one of the two gears associated with a corresponding eccentric, or the other.

In one of the two axial positions of the timer gear, a flat portion on the hub of one of the eccentric gears is continually in engagement with the peripheral ridge of the timer gear. The other eccentric gear, however, has the flat portion on its hub in engagement with the timer gear ridge for much of the cash register cycle, but the ridge is relieved to permit rotation of the eccentric gear by mating gear teeth on the timer gear, at two points around the periphery of the timer gear. Similarly, when the timer gear is in its other axial position, the other eccentric gear is actuated in a corresponding manner.

The timer gear is axially shifted by a pair of pins mounted on an enclosing housing. These pins are mounted on a frame which moves parallel to a diameter of the timer gear, and in the rest position between cash register cycles, they are located adjacent ramps or inclined surfaces on the timer gear which extend along a diameter of the timer gear. When the enclosing carriage is moved to a position corresponding to the ADD cycle of the cash register, the pins are moved radially on the ramps to push the timer gear to one axial position. When the enclosing housing is moved in the other direction, the pins ride on the ramps in the other direction and push the timer gear to its other axial position. Once a cash register cycle starts and the timer gear starts to rotate, however, at least one of the pins is locked in a groove, thus preventing movement of the enclosing selection housing.

Accordingly, one feature of the invention involves the selective actuation of two eccentric assemblies to provide selective relative motion in different directions when one of the eccentric assemblies is held and the other is moved. J

In accordance with another aspect of the invention, the rotation of two shafts may be selectively controlled by a modified geneva-type action in which a timer gear is provided with two axial positions, to selectively move two gears connected respectively to the two shafts. In one of the two axial positions, a first one of two gears is intermittently rotated while the second is held in a fixed position, while in the other axial position of the timer gear, the second gear is rotated while the first is held in a fixed position.

BRIEF DESCRIPTION OF THE DRAWINGS Other aspects and features of the invention will become apparent from a consideration of the detailed description and from the drawings, in which:

FIG. I is an assembly view showing the complete cash register together with the cash drawer on which it stands;

FIG. 1A is a view of the business machine showing both sets of display windows;

FIG. 2 is an exploded view of the operating portions of the cash register of FIG. 1 without the cash drawer and with the cover removed;

FIG. 3 is a perspective view of the keyboard assembly;

FIG. 4 is a side view of a single key row;

FIG. 5 is an end view of the key row shown in FIG. 4;

FIG. 5A shows a single key of the keyboard;

FIG. 6 is a view of the two slides which prevent actuation of any other keys and provide other functions when one cash register key in a given key row is depressed;

FIG. 7 is a side view showing the mode of operation of the flexible digit tapes;

FIG. 8 shows the by-pass stops secured to the ends of each digit tape;

FIG. 9 is an isometric view of the digit tapes and their stops;

FIG. 10 shows the tape constraining frame or assembly cut away to show several of the tapes;

FIG. 11 shows the accumulator assembly and the engagement with the digit tapes;

FIG. 12 is a partial cross-sectional view of the display assembly;

FIG. 13 is a schematic cross-sectional view showing the relationships of the principal components of the cash register;

FIG. 14 is a side view of the register which shows the accumulator movement control arrangements to ad vantage;

FIGS. 15, 16, 16A, and 16B are various views of the accumulator control timing gear and the associated accumulator camming control gears;

FIG. 17 shows the drive line including the gears which engage the perforations in the flexibly digit tapes;

FIG. 18 shows a positively driven disc and drive gear pair, which are coupled together by a spring biased pawl;

FIG. 19 shows the drive sector gear and the driven gear at one end of the drive line;

FIG. 20 shows an accumulator gear together with the stop mechanism which come into play as information is being transferred from the accumulator to the display;

FIG. 21 shows the accumulator mask moving mechanism;

FIG. 22 is a timing chart showing the timing of the operation of certain parts of the cash register during an operating cycle;

FIG. 23 is a side view of an alternative cash register construction; and

FIGS. 24 and 25 are side and front views of the details of the accumulator moving and control mechanisms.

DETAILED DESCRIPTION Referring more particularly to the drawings, FIG. 1 shows the cash register assembly 40 standing on the cash drawer assembly 42. The viewing windows 43 for the clerk and 45 for the customer are shown in FIG. 1A. As seen in both FIGS. 1 and 2, the cash register includes a keyboard assembly 100, a base and power unit 200, an indicator or display assembly 300 and an accumulator assembly 400. Also visible in FIG. 2 are the ADD or TOTAL control member 450 which determines the mode of operation of the accumulator 400, as implemented by the accumulator timing gear 460 and its associated mechanical mechanisms.

With reference to FIG. 3, the keyboard 100 includes a plurality of key rows 10] through 106. The individual key row moldings are provided with recesses at opposite ends for ease in mounting the key rows side by side on the shafts I12 and 114. As mentioned above, most of the major subcomponents of the present cash register are mounted on shafts for ready assembly with the side plates of the base unit 200.

As shown to better advantage in FIGS. 4, 5, A, and 6, each key row 101 through 106 may be provided with a set of nine keys 121 through 129, with key 122 being depressed in the illustrative embodiment of FIG. 4. Each key row is also provided with two interlock slides 132 and 134, shown in FIG. 6. The key row assembly is provided with a single spiral biasing spring 136. As

shown in FIGS. 4 and 5, the biasing spring 136 extends through the interlock slides 132 and 134 to bias them to their normal positions. In addition, the biasing for each of the plastic keys 121 through 129 is provided by the same single spring 136. As shown in FIG. 4, for example, the spring 136 is extended at 138 to provide upward pressure on the key 122 through the integral recess molded into the rear of the key 122. FIG. 5A shows a key 122 separately, to indicate the structure of the integral key. The head of the key, the spring 141 which holds the keys in frame 101, the slide engaging stud 140, and the spring engaging recess 143 are all molded into the key as it is formed.

The lower end 142 of the key 122 protrudes below the key row assembly 101 and below the interlock slides 132 and 134 to block the movement of the stop which is secured onto one end of the flexible tapes in a manner to be discussed in greater detail below. The lightweight molded plastic keys 122 would normally not have sufficient strength to stop a heavy metal rack as employed in conventional cash registers. However, the flexible tapes which are used instead of racks in the present cash register have such a light weight and such low inertia that there is no problem with the end 142 of the lightweight plastic keys stopping the flexible plastic tapes.

Concerning the operation of thermetal slides 132 and 134, the spring 136 extends through slot 139 in slide 132 at the left-hand end of slide 132 where there is no interference with slide 134. Similarly, the other end of spring 136 extends through slot 147 in slide 134 at its right-hand end to avoid interference with slide 132 in the biasing or positioning function.

The sole function of slide 134 is to control the accumulator zero stop 143. When none of the nine keys 121 through 129 of a key row is depressed, the accumulator zero stop 143 is in one position; however, when any key, such as key 122, is depressed, the slide 134 is shifted to the left and accumulator zero stop 143 is rotated to permit operation of the associated accumulator register.

The slide 132 provides interlocking functions. It is normally biased so that the angle surfaces 144 underlie the key studs 140. When a key is depressed, the stud initially moves the locking slide 132 to the right and then enters the recess 146 which is below the slanted surface 144.

Once the ADD or TOTAL key 450 is hit, the keyboard control shaft 150 is actuated to the left to engage the arm 152 which depends from the slide 132. This moves the slide 132 to the left so that the flat sur faces 154 on slide 132 underlie the studs 140 of the keys, and thus effectively lock them out and prevent further action of the keyboard. Toward the end of each cycle, the shaft 150 is moved to the right to release all of the keys.

It is again noted that the entire key row assembly only includes fourteen elements and particularly that only two slides are employed. This is in sharp contrast with 53 parts included in the key row assembly of at least one widely used commercial cash register. Further, the single spiral spring 136 not only provides the biasing for all of the keys of each key row but also biases the two slides 132 and 134 to their proper positrons.

FIG. 7 shows schematically the mode of operation of the plastic tapes 60 which form a key component in the present invention. In the course of the cycle of operation of the present cash register, the digit tapes are always coupled to the display wheels of the indicator as sembly 300. When cash register operation is initiated by pressing the ADD" control, the digit tapes are restored to their zero" state in which the tapes are shifted to the front, or the left of the machine as shown in FIG. 7. The flexible tapes are then driven forward by the drive line gears 202 until the stop 62 which is secured to the end of the tape 60 engages the lower end of a depressed key 126, as shown in FIG. 7. As the flexible digit tape moves forward, the gears of the accumulator 400 are rotated, with the gears of the item total accumulator engaging one of the sets of perforations 64, while the gear teeth on the grand total accumulator engage the other set of perforations 66 in the flexible plastic tape 60. When the stop 62 engages the lower end of the key 126, the drive line 202 releases the force applied to the tape 60, as discussed in greater detail below, the indicator 300 displays the digit corresponding the depressed key 126, and the accumulator 400 adds the digit in both the item total and the grand total registers.

As the flexible tape is driven past the gears of the drive line 202, it is deflected downwardly by the tape constraining enclosure 204 and also engages the rear casing 206 of the cash register. By this technique, the use of additional rearwardly extending space for the cash register to accommodate the tapes is avoided, and the complexity of the step-up and step-down gearing, which is required in present cash registers, is also eliminated. The dual goals of compactness and simplicity are thus achieved primarily by the use of very flexible tapes which are bent around within the small confines of the present compact cash register.

The movable tape is provided with a plastic retaining element 68 for the stop 62. The retainer 68 extends through an opening in the tape 60 and serves as a carrier for the stop 62. When the tapes are driven to the zero" position so that the stop 62 moves to its extreme left or front position, the stop 62 must pass under a depressed key such as key 126 in FIG. 7. Under these conditions, it pivots downwardly, as indicated at 70 in H0. 8. Under these conditions, the tongue 72 of the tape 60 resiliently flexes down also, as indicated in FIG. 8.

in FIG. 9, the thickness of the tape is exaggerated to some extent. The tapes are actually about 0.020 inch thick. The tapes are 13% inches long and five-eighths inch wide.

FIG. 10 shows the frame 204 which constrains the tapes 60 to follow a rectilinear path in the regions where the stops 62 underlie the keyboard 100. As shown in FIG. 10, the frame 204 is provided with slots 206 through which the stops 62 extend to engage the lower ends of depressed keys. In addition, the drive gears engage the tapes through the long slots 208 which are aligned with one of the sets of perforations in each tape 60. The slots 210 accommodate accumulator transfer bails, which come into play when transfers are made from one register to the next higher order. The accumulator register gears engage the tapes 60 through the slots 214, with the item total gears engaging the right-hand row of perforations, and the grand total gears, the left. The gears for driving the set of indicator wheels which are read by the clerk or the operator of the cash register extend through the front of slots 208. The slots 212 accommodate an accumulator detent. The shorter set of slots 216 which are interleaved with the slots 208 are located between adjacent tapes and accommodate the gears which drive the customer indicator wheels as described below.

In general, the frame 204 provides the support and channeling necessary to constrain the plastic tapes 60 to the paths required for their proper operation. With the indicated physical configuration, the tapes 60 have operated several million times without physical signs of wear and without tape failure.

The accumulator assembly 400 is shown in FIG. 11. The grand total register includes the indicator wheels 401, 403, 405, etc., while the subtotal is displayed on the indicator wheels 402, 404, 406, etc. The gears secured to the indicator wheels 401, 403, 405, etc., associated with the grand total engage the right-hand set of perforations on the digit tapes 60 as shown in FIG. 11, while the gears associated with the subtotal wheels 402, 404, 406 engage the left-hand set of perforations of the tapes 60.

The view of FIG. 11 is taken from the rear of the machine looking down at the tapes 60 between the accumulator and the indicator wheels. Above the accumulator indicator wheels is a mask 412 containing a series of windows 414. The mask 414 is normally positioned so that the operator of the cash register may view the subtotal registered on a particular customer's sale through the windows 414. When the key locking the cash register is employed, however, the mask 412 is shifted laterally to permit the viewing of the grand total register wheels through windows 414 to the exclusion of the subtotal.

FlG. 12 is a front view of the indicator or display assembly 300. The indicator assembly includes two sets of interleaved indicator wheels, the first set 308 being visible from the front of the machine by the operator, while the second set 310 is observable by the customer from the rear of the machine. In addition, of course, the position of the wheels having more or less significant numbers must be reversed, with the least significant digit appearing to the right in the set of the wheels 308 observed by the clerk while the least significant digit observed by the customer must be on the left-hand indicator wheel 310, as seen in FIG. 12.

As described below in connection with FIG. 13, the gears 306 in the foreground are directly coupled to one of the two rows of perforations in the tape 60. Gears 306 engage gears 312 associated with the clerk indicator wheels 308. The drive for the customer indicator wheels 310 is somewhat more complex as it involves the gears 304 (to the rear in FIG. 12) which mesh with the gear teeth 314 associated with the customer indicator wheels 310. The shaft 316 upon which the indicator wheels 308 and 310 are mounted is supported in the keyhole slot 318 as shown, for example, in FIGS. 2 and 14.

FIG. 13 is a schematic cross sectional view showing the relative positions of most of the main rotatable components or assemblies. Following the application of power to the cash register when the ADD or TOTAL control is pressed, the motor 222 is coupled through a rubber belt 224 to the power speed reducer assembly 226. An auxiliary hand-crank drive coupling is also connected to the power speed reducer 226 through gear 228. The cam line 230 is driven from gear 232 on the speed reducer assembly 226 through gear 236 on the cam line. The clutch gear 236 is mounted on the cam line assembly 230. The metal drive sector gear 238 is pivoted at 240 and is bent into a U-shaped form with a cam pin 242 securely fastened to the inner leg 244 of the drive sector gear assembly. The pin 242 rides in a groove in a cam in the cam line assembly 230. The power for the drive gears 246 is provided through the teeth 248 of the metal drive sector gear 238. These teeth 248 mesh with the gear 250 which is fixed or pinned to the drive line shaft 252.

As in the case of a number of the assemblies of the present machine, the drive line shaft 252 is cut away in two areas from end to end. The gear 250 is provided with matching protrusions at its center. Accordingly, it is rigidly secured against rotational movement relative to the shaft 252, and is pinned to this shaft. Where it is desired to mount other freely rotatable gears or other mechanisms on the same shaft, they may be formed with a circular opening in the center. Without the keying structure to lock or pin them to the drive shaft 252, they are free to rotate. Accordingly, a single shaft with longitudinal slots may serve a dual purpose, acting both as a drive shaft and also as an axle for free rotation of other coaxially mounted elements.

From the drive gears 246, power is transmitted directly to the perforated tapes 60. As the sector gear follows the programmed camming motion of the cam line assembly 230, the tapes 60 are initially restored to their zero" position and are then driven forward by the drive gears 246 until they engage stops such as the lower end of depressed key 126 (See FIG. 7). A clutching mechanism, to be described in greater detail below, then releases the drive to the individual tapes and permits the tape 'to remain in its position corresponding to the depressed digit key.

The accumulator assembly 400 has its principal axis located at point 425. As indicated by the arrows, the accumulator may be moved down and up for engagementor disengagement, respectively, with the tapes 60, or may be moved to the rear toward the indicator assembly 300 to transfer totals stored in the accumulator to the indicator assembly. The circles 422, 424 and 426 in FIG. 13 represent the mechanisms involving gears, camming surfaces and a Geneva-type movement which control the movement of the accumulator registers. These mechanisms will be described in greater detail below.

Included in the indicator assembly 300 are one set of indicator wheels which are visible by the customer and another set of indicator wheels which may be viewed by the clerk. The customer indicator wheels are driven by the transfer gears 302 through a set of gears which are mounted for free rotation on the drive shaft 252 and which mesh with the customer indicator drive gears 304. The clerk indicator display wheels, however, are driven by the gears 306 directly from the tapes 60.

When information is being transferred from the accumulator registers to the indicator assembly, the shaft 425 moves to the right and the indicator assembly is energized through the gears 308. Although the gears 306 are close to gears 308, there is clearance and no direct interaction between gears 306 and 308.

Many of the critical details of the structure shown schematically in FIG. 13 will be discussed in greater detail below in connection with other FIGURES in the drawing.

FIGS. 14 through 16 are particularly useful in describing the mode of operation of the accumulator 400. The accumulator can move either perpendicular to the keyboard or parallel to it. As indicated by the arrows and legends on the face of the accumulator side frame member 470 in FIG. 14, the accumulator assembly moves up and down for engagement and disengagement with the digit tapes on "ADD" cycles and moves to the rear and forward in the course of TOTAL cycles in transferring the contents of its subtotal register to the display unit 300. An ADD or a TOTAL cycle is initiated by pressing the key 450 in the forward or the rear direction, respectively. The key 450 is pivoted at point 452 and has a flexible arm 454 which is pivotally connected to the control linkage 456 at point 458.

The central shaft 462, to which the timer gear 460 is secured, is fixed in position. When the ADD or TOTAL control lever 450 is pressed, the linkage 456, which includes the frame 464 enclosing the timer gear 460, is

moved to the front or the rear as indicated by the arrows adjacent the numeral 464 in FIG. 14. On ADD cycles the frame 464 moves to the rear and on TOTAL cycles the frame 464 moves toward the front of the machine. Between cycles the frame 464 is maintained in a position such that the shaft 462 is centrally located with respect to the slot 466. In the arrangement shown in FIG. 14, the relationship of the parts indicates that an ADD cycle is underway.

The movement of the accumulator is controlled by three eccentrics 472, 473' and 474'. In FIG. 14, the numerals 473 and 474 are directed to gears which conceal the eccentrics 473' and 474, which are located directly behind them. As clearly shown in FIGS. 24 and 25, the eccentrics are mounted to rotate in the rectangular slots 476, 477, and 478. A corresponding set of three eccentrics mounted on corresponding shafts are located at the other side of the register. One of these eccentrics 474" is shown in FIG. 25.

The eccentric 472 and 474', which rotate in slots 476 and 478 control the upward and downward movement of the accumulator register, while the eccentric 473 in slot 477 controls the forward and backward movement of the accumulator register on TOTAL cycles. During ADD cycles the eccentric 473' is held against rotation while the gear 474 and associated eccentric 474' and eccentric 472 (which is geared to 474) are rotated to raise and lower the accumulator. Similarly, on TOTAL cycles the gear 473 and its associated eccentric 473' are rotated to move the accumulator assembly to the rear and forward while the gear 474 and its associated eccentric 474' and the paired eccentric 472 are held against rotation to provide guiding action. Eccentrics 474' and 472 are geared to rotate together by gear 422 formed as part of a single molding with eccentric 474" (see FIG. 25) and gears 424 and 426 (See FIG. l3). Gears 422 and 426 are pinned to the shafts on which they are mounted, but idler gear 424 is free to rotate on the shaft on which eccentrics 473 and 473" are fixedly secured.

The implementation of the described motion of the gears 474 may be better understood by reference to FIGS. 16, 16A, and 168. In FIG. 16A, the timer gear 460 is shown in solid lines in the ADD position. Under these circumstances the gear 473 has two flat portions on its hub 480 which engage the periphery of the ridge 482 on the timer gear to preclude rotation of the shaft 481 and its associated eccentric. Gear 474, however, which controls the movement of an associated eccentric on shaft 484, and the mechanically coupled eccentric 472, are intermittently rotated. FIG. 168 shows the arrangements for selectively and intermittently locking and rotating the gears 473 or 474. In FIG. 16B, the gear 474 is shown with the flat portion 486 of its hub 488 engaging a flat portion of the ridge 482. As the timer is rotated, the gear teeth 474 engage the teeth 490 on the timer gear. The ridge 482 is cut away as indicated by the dashed lines 492 to permit rotation of the shaft 484 under the control of the meshing gears 474 and 490. This arrangement is shown as viewed from above in FIG. 16A.

As shown in FIG. 16, the timer gear 460 has two sets of gear teeth 490 and 494 which engage the gear teeth 474 to first rotate the accumulator down for engagement with the tapes and subsequently shift the accumulator up to the disengaged rest position which it maintains between cycles. During this complete ADD cycle, the central shaft 481 and the eccentric which is associated with it and the gear 473 is held against rotation by the flat portion on hub 480 being in continuous engagement with the periphery of ridge 482.

On TOTAL cycles, however, the function of gears 473 and 474 are interchanged. This is accomplished by shifting the timing gear wheel 460 to the position, as shown in dashed lines, in FIG. 16A. The flat portions on the hub 488 of gear 474 are continuously in engagement with the periphery of ridge 482 when the timer gear is in this shifted position. However, the gear teeth 473 are now aligned with teeth 496 of timer Wheel 460 and gear 473 is permitted to rotate as a result of the displacement and the presence of the recess 498 in the ridge 482 adjacent the gear teeth 496.

The timer gear 460 is keyed to the shaft 462 but is permitted to slide back and forth as indicated by the solid and the dashed line showings of FIG. 16A. In the neutral position, between cycles, the pins 502 and 504 are located in contact with inclined faces on the timer gear wheel surfaces shown at 506 in FIG. 16 of the drawings. When the ADD or TOTAL control 450 is pressed, the slide 464 moves from its neutral position so that one of the pins such as 504 which is visible in FIG. I4 is permitted to ride in a track such as track 506 as shown in FIG. 16. The other pin will then be located close to the hub of the timer gear 460 and will rotate on a raised surface in this location and will maintain pressure on the timer gear wheel 460 forcing it in the desired in' or out" position for TOTAL or ADD cycle operations, respectively.

Incidentally, for completeness, it should be noted that the showing of FIG. is from above with the timer gear in the in position for a TOTAL cycle. This is in contrast to the showing of FIG. 16A in which the solid line position is the ADD position.

FIG. 17 is a rear view of the drive line including the various gears which are mounted on the central shaft 252 of the drive line assembly. As may be seen from FIG. 13, the drive shaft is located below the tapes 60 so that the drive gears 246 may readily engage the tape toward the rear of the cash register as its path is deflected downward. As discussed above in connection with FIG. 13, it is only alternate gear assemblies 246 which have inner hubs which are pinned to the shaft 252 and which rotate with it. The alternate gears 247 are mounted on the same shaft as the drive gear assem blies 246 but are not pinned to it, so are free to rotate about shaft 252.

As mentioned above, the customer indicator display wheels must be rotated in synchronism with the clerk indicator display wheels, but the digits are reversed in their position. To accommodate this purpose, transfer gears 302 are provided. Three transfer gears 302 are shown mounted on and pinned to shaft 303. The gear 302 is rotated with the drive gear 246 and constrains the two other gears 302' and 302" to rotate in synchronism with it. This causes the right-hand customer indicator drive gear 247 to rotate in step with the left-hand drive gear 246 as shown in FIG. 17. Similarly, the printer gear wheel 602 is driven by transfer gear 302" to establish proper information relating to the least significant digit of the information registered by the left-hand drive gear 246.

As shown in FIG. 18, the drive gears 246 are driven from the drive shaft 252 through a drive hub 262 which is provided with a disc portion 264 and a central cylindrical portion 266 which is keyed to the drive shaft 252. The cylindrical central hub 268 of the drive gear assembly 246 rotates on the cylinder 266. The pawl 270 is pivoted at 272 and is biased to the indicated position by spring 274. This normally holds the bearing member 276 of the pawl assembly 270 in the pocket 278 of the drive gear assembly.

Under normal conditions as an ADD cycle of the cash register is initiated, the drive shaft 252 drives the drive hub 262 in the direction indicated by the arrow 280, in restoring the tapes to the "0 position. During this operation, of course, the teeth of drive gears 246 are in engagement with one of the sets of perforations in the digit tape 60. The direction is reversed as the tapes move toward engagement with depressed keys. When the stop on the tape 60 engages a depressed key, the tape immediately stops. This stops the drive gear 246 and the bias of spring 274 is overcome, permitting the pawl 270 to come out of the pocket 278 and freely rotate in the recess 282 of the drive gear assembly 246. In this way, each drive gear 246 stops at an angular position determined by the depressed keys on the keyboard.

With reference to FIG. 19, the metal drive sector gear 238 is shown pivotally mounted about the shaft 240 for movement under the control of the cam 292 having a cam slot 294 with which the pin 242 coacts. The plastic main drive gear 250 is mounted on the drive shaft 252 for rotation in accordance with the movement of the drive sector gear 238, causing, for example, initial restoration of the tapes to the zero position and subsequent rearward movement of the tapes on the power portion of the cycle.

FIG. 20 shows one of the accumulator gears 402 associated with the accumulator indicator wheel as described above in connection with FIG. 11. Within the indicator and gear wheel assembly 402 is a central hub 422 pinned to the central accumulator shaft 424. On normal ADD cycles, the gear 402 rotates in the counterclockwise direction as indicated by arrow 426. With this direction of rotation, the pawl 428 is pivoted against the pressure of spring 430 when it is engaged by the accumulator zero stop 432. The pawl 428 then swings away from its restrained stop 434 toward the center hub 422 of the assembly, permitting continued rotation of the accumulator wheel assembly 402.

On TOTAL cycles, however, when the contents of the accumulator register are being transferred to the display or indicator assembly 300, the accumulator gear assembly 402 rotates in the clockwise direction as indicated by arrows 436. The pawl 428 is mounted on pivot point 438 which is fixed to the stationary center assembly mounted on and pinned to shaft 424. This is in contrast to the gear and indicator assemblies 402 which are mounted for free rotation on the same shaft 424. Accordingly, when the accumulator register is shifted to the rear and driven through gear 308 from power supplied through the indicator assembly gearing, the gears 402 rotate in the clockwise direction until the zero stop 432 engages the pawl 428. When this occurs, the release of the drive gears from the drive line, as discussed in detail above in connection with FIG. 18, occurs. Accordingly, the indicator wheels will stop in a position corresponding to that which has been registered in the accumulator TOTAL registers.

FIG. 21 shows the mechanism for shifting the mask 412 as shown in FIG. 11. In FIG. 21, the lock 522 controls the movement of the mask 412. The block 524 is fixed in position as is the support 526 for the spring 528. Incidentally, the spring 528 is secured in an opening 530 in the mask 412 to bias the mask to its position in which the subtotal rather than the grand total is revealed. When a key is inserted into the key slot 532, the cylindrical member 522 together with the cam 534 and the fork member 536 secured to the mask 412 may be moved to the right rear as shown in FIG. 21. This shifting of the mask 412 serves to reveal the grand total set of indicator wheels instead of the subtotal, as described in some detail in connection with FIG. 11. When pressure is released from the key, the slide is returned to the front left position as shown in FIG. 21 by the force of the leaf spring 528. Removal of the key locks the mask in place.

FIG. 22 is a timing diagram showing the relative time of operation of the accumulator movement, the timer gear shifting, and the drive rack motion. In reviewing the cycle from to the 360 termination of the cycle, with the degrees referring to the angular orientation of the timer gear 460 and the cam 292 of FIG. 19, it may be noted that the drive racks are initially restored. are held in the 0 position from about 100 to about 140, and digit selection takes place from about l40 to 280. The cam slot 294 (See FIG. l9) of course follows the displacements indicated in the Drive Tape" plot of F I0. 22.

When it occurs, the timer gear shifting takes place at an early point in the cycle. However, the timer gear does not shift on successive ADD cycles, for example.

When an ADD cycle is followed by a TOTAL cycle, or vice-versa, the timer gear is shifted from one position to the other as indicated by the solid line or the dash line plots.

The accumulator-movement occurs and This is the time when the accumulator is either moved down into engagement with the racks (now in their 0 position) or to the rear into driving engagement with the display assembly. Following completion of the drive rack selection (which occurs at about 280) the accumulator is restored to its regular position. This occurs from about 310 to 340.

An alternate embodiment of the invention is disclosed in FIG. 23. The cash register as shown in FIG. 23 is generally patterned after the cash register described hereinabove, but has two of the main assemblies shifted in a manner which provides certain economies in parts.

Referring to FIG. 23 in greater detail, it shows the main frame structure 702 of the cash register, the keyboard 704, the accumulator register 706, the drive assembly 708 and the indicator assembly 710. As in the case of the cash register described in connection with FIGS. 1 through 22 of the drawings, the present cash register includes a series of flexible digit tapes 712. By shifting the drive 708 from a position below the digit tapes 712 to a position above the digit tapes, the indicator assembly 710 is raised for better visibility, and certain transfer gearing is eliminated. The transfer gears 714 serve the same functions as described above in connection with the transfer gears 302, but some of the gear assemblies such as gears 304, 306 and 308 may be eliminated. As in the case of the other embodiment of the cash register, the accumulator 706 is shifted both up and down for ADD cycles and to the rear and forward for TOTAL cycles. Apart from the shifting of the position of the drive line and the concomitant changes in structure such as those mentioned above, the embodiment of FIG. 23 operates in substantially the same manner as that of the other embodiment of the invention.

Concerning the materials which may be employed in the implementation of the illustrated cash register, wide use is made of plastics. One of the preferred plastic materials is a DuPont material known as DEL- RIN. This is a homopolymer of formaldehyde with a very low coefficient of friction, good flexibility and high strength. DELRIN is described, for example, in the March 1970 issue of Materials Engineering. The digit tapes may be made of DELRIN of a thickness of about 0.020 inch as noted above. CELCON is a copolymer of formaldehyde and could also be used for many other parts of the cash register. Fiberglass-filled nylon is also employed for various parts, for example, for the drive hubs. It is, of course, undesirable to have two parts of the same material having surfaces which slide on one another, as this tends toward increased friction and possible binding. Another material which may be used in the cash register, for example in the key row, is NORYL, which is a fiberglass-filled polyphenol oxide. Of course, a number of parts of the register are made of steel, where high strength is required. These principally include the frame of the machine, the shafts, and certain key high-strength parts such as the drive sector gear.

The foregoing description has been focused primarily on the structural features and interrelationships which are different from those found in conventional cash registers. Details of well-known structures and relationships, and arrangements known to those skilled in the art have been eliminated for purposes of brevity and clarity.

In the course of the present description of the invention, the compactness of the cash register has been mentioned at several points. As a matter of completeness, it may be noted that the overall dimensions of the base or cash drawer upon which the rest of the cash register sits, are approximately /2 inches wide, by 17 inches deep, by 4 inches high. The cash register apparatus excluding the cash drawer assembly is approximately 14 inches wide, by 16 inches deep, by ll inches high.

In closing it is noted that other known arrangements may be substituted for specific components disclosed in the present description, and various alternative constructions may be employed. For example, in connection with the eccentrics, a set of six eccentrics has been disclosed for moving the accumulator. However, the relative positioning of two plates may be accomplished merely by using the three eccentrics located at one side of the cash register. in that event, the pair of eccentrics would control movement in one direction while the single eccentric would provide movement in the other direction. Further, controlled differential movement may be accomplished using only two eccentrics with clearance being provided only on one side of each eccentric. Under these circumstances, the fixed eccentric would serve as a pivot point while the moving eccentric would rotate one member relative to the other. In such arrangements, limitations on the angular rotation of the eccentrics would be appropriate to avoid mechanical interferences. Concerning the timer gear and the modified geneva gear mechanism, instead of axially shifting the timer gear, both of the two smaller gears could be shifted on their shafts with respect to the position of the timer gear to select the desired cash register cycle.

Other similar variations within the scope of one skilled in the art would also be possible.

What is claimed is:

1. A cash register comprising:

a keyboard;

a display for indicating amounts entered on said keyboard;

an accumulator;

mechanical means for transferring digit information from said keyboard to said display; and

means for selectively moving the accumulator either down into engagement with said mechanical means or to the rear for transferring information stored in said accumulator to said display, said moving means including a geneva-type mechanism having a timer gear for controlling the motion of said accumulator.

2. A business machine comprising:

a keyboard;

a display for indicating amounts entered on said keyboard;

an accumulator;

mechanical means for transferring digit information from said keyboa d to said display; and means for selective y moving the accumulator either in one direction into engagement with said mechanical means or in another direction for transferring information stored in said accumulator to said display, said accumulator moving means including two eccentric assemblies in mechanical coupling relationship with said accumulator.

3. A business machine as defined in claim 2 wherein one of said eccentric assemblies includes two coupled eccentrics located in openings having clearance in one direction, and the other eccentric assembly includes an eccentric located in an opening having clearance in the other direction.

4. A business machine as defined in claim 2 wherein means including a geneva-type mechanism having a timer gear is provided to control the motion of said eccentric assemblies.

5. A business machine as defined in claim 4 wherein means are provided for shifting the axial position of said timer gear to selectively provide vertical or horizontal motion of said accumulator.

6. A business machine as defined in claim 5 wherein ADD or TOTAL control means are provided to selectively move said timer gear to one axial position on ADD cycles and to another axial position on TOTAL cycles.

7. A business machine as defined in claim 2 wherein said accumulator moving means comprises:

means including a pair of coupled eccentrics for moving said accumulator in one direction;

means including a third eccentric for moving said ac cumulator register in another direction under the guidance of said first pair of eccentrics and under control of said third eccentric;

a first geneva gear connected to said pair of eccentrics;

a second geneva gear connected to said third eccentric',

means including a timer gear for controlling the motion of said first and second geneva gears to hold one of them against rotation and to intermittently rotate the other; and

means for axially shifting said timer gear to hold one of said geneva gears fixed while rotating the other, or to hold the second geneva gear fixed while in termittently rotating the first.

8. A business machine as defined in claim 7 wherein said means for axially moving said timer gears includes a movable housing and opposed camming pins. 

1. A cash register comprising: a keyboard; a display for indicating amounts entered on said keyboard; an accumulator; mechanical means for transferring digit information from said keyboard to said display; and means for selectively moving the accumulator either down into engagement with said mechanical means or to the rear for transferring information stored in said accumulator to said display, said moving means including a geneva-type mechanism having a timer gear for controlling the motion of said accumulator.
 2. A business machine comprising: a keyboard; a display for indicating amounts entered on said keyboard; an accumulator; mechanical means for transferring digit information from said keyboard tO said display; and means for selectively moving the accumulator either in one direction into engagement with said mechanical means or in another direction for transferring information stored in said accumulator to said display, said accumulator moving means including two eccentric assemblies in mechanical coupling relationship with said accumulator.
 3. A business machine as defined in claim 2 wherein one of said eccentric assemblies includes two coupled eccentrics located in openings having clearance in one direction, and the other eccentric assembly includes an eccentric located in an opening having clearance in the other direction.
 4. A business machine as defined in claim 2 wherein means including a geneva-type mechanism having a timer gear is provided to control the motion of said eccentric assemblies.
 5. A business machine as defined in claim 4 wherein means are provided for shifting the axial position of said timer gear to selectively provide vertical or horizontal motion of said accumulator.
 6. A business machine as defined in claim 5 wherein ADD or TOTAL control means are provided to selectively move said timer gear to one axial position on ADD cycles and to another axial position on TOTAL cycles.
 7. A business machine as defined in claim 2 wherein said accumulator moving means comprises: means including a pair of coupled eccentrics for moving said accumulator in one direction; means including a third eccentric for moving said accumulator register in another direction under the guidance of said first pair of eccentrics and under control of said third eccentric; a first geneva gear connected to said pair of eccentrics; a second geneva gear connected to said third eccentric; means including a timer gear for controlling the motion of said first and second geneva gears to hold one of them against rotation and to intermittently rotate the other; and means for axially shifting said timer gear to hold one of said geneva gears fixed while rotating the other, or to hold the second geneva gear fixed while intermittently rotating the first.
 8. A business machine as defined in claim 7 wherein said means for axially moving said timer gears includes a movable housing and opposed camming pins. 